NZ737831B2 - Profile - Google Patents
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- NZ737831B2 NZ737831B2 NZ737831A NZ73783116A NZ737831B2 NZ 737831 B2 NZ737831 B2 NZ 737831B2 NZ 737831 A NZ737831 A NZ 737831A NZ 73783116 A NZ73783116 A NZ 73783116A NZ 737831 B2 NZ737831 B2 NZ 737831B2
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- New Zealand
- Prior art keywords
- profiles
- geotechnical
- profile
- fibers
- internal reinforcing
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- 230000003014 reinforcing effect Effects 0.000 claims abstract description 149
- 239000000835 fiber Substances 0.000 claims abstract description 138
- 238000000034 method Methods 0.000 claims abstract description 49
- 239000012783 reinforcing fiber Substances 0.000 claims abstract description 36
- 239000012815 thermoplastic material Substances 0.000 claims abstract description 30
- 230000002787 reinforcement Effects 0.000 claims abstract description 15
- 238000004519 manufacturing process Methods 0.000 claims abstract description 12
- 229920001169 thermoplastic Polymers 0.000 claims description 43
- 239000004416 thermosoftening plastic Substances 0.000 claims description 43
- 238000003490 calendering Methods 0.000 claims description 38
- 239000003365 glass fiber Substances 0.000 claims description 38
- 230000002265 prevention Effects 0.000 claims description 14
- 238000005452 bending Methods 0.000 claims description 13
- 239000004033 plastic Substances 0.000 claims description 12
- 229920003023 plastic Polymers 0.000 claims description 12
- -1 basalt Substances 0.000 claims description 11
- 229910000831 Steel Inorganic materials 0.000 claims description 10
- 239000010959 steel Substances 0.000 claims description 10
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 claims description 9
- 238000001125 extrusion Methods 0.000 claims description 8
- 229920001944 Plastisol Polymers 0.000 claims description 7
- 239000011521 glass Substances 0.000 claims description 7
- 239000000463 material Substances 0.000 claims description 7
- 239000004999 plastisol Substances 0.000 claims description 7
- 239000004952 Polyamide Substances 0.000 claims description 6
- 239000004760 aramid Substances 0.000 claims description 6
- 229920003235 aromatic polyamide Polymers 0.000 claims description 6
- 239000004744 fabric Substances 0.000 claims description 6
- 229920002647 polyamide Polymers 0.000 claims description 6
- 239000000017 hydrogel Substances 0.000 claims description 3
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- 239000011159 matrix material Substances 0.000 description 67
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- 239000004698 Polyethylene Substances 0.000 description 6
- 229920001155 polypropylene Polymers 0.000 description 6
- 229920001187 thermosetting polymer Polymers 0.000 description 6
- 229920000049 Carbon (fiber) Polymers 0.000 description 5
- 239000004917 carbon fiber Substances 0.000 description 5
- 239000002356 single layer Substances 0.000 description 5
- 229910052782 aluminium Inorganic materials 0.000 description 4
- XAGFODPZIPBFFR-UHFFFAOYSA-N aluminium Chemical compound [Al] XAGFODPZIPBFFR-UHFFFAOYSA-N 0.000 description 4
- 229920001903 high density polyethylene Polymers 0.000 description 4
- 239000004700 high-density polyethylene Substances 0.000 description 4
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- VNWKTOKETHGBQD-UHFFFAOYSA-N methane Chemical compound C VNWKTOKETHGBQD-UHFFFAOYSA-N 0.000 description 2
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- 101100025412 Arabidopsis thaliana XI-A gene Proteins 0.000 description 1
- 238000006424 Flood reaction Methods 0.000 description 1
- BZHJMEDXRYGGRV-UHFFFAOYSA-N Vinyl chloride Chemical compound ClC=C BZHJMEDXRYGGRV-UHFFFAOYSA-N 0.000 description 1
- 238000009412 basement excavation Methods 0.000 description 1
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- 125000000391 vinyl group Chemical group [H]C([*])=C([H])[H] 0.000 description 1
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Abstract
Problems of recycling effectively whilst addressing durability requirements without increased weight or overall production costs are addressed. Disclosed are methods of manufacturing geotechnical profiles, characterized in that thermoplastic material is plasticized in an extruder, after which it is pressed through a cross die unit and internal reinforcing profiles in a form of flat bars, arched elements, angled elements, ribbed profiles or sections of any geometry comprising reinforcing fibers are entered at least in selected cross-section areas of the geotechnical profile whereas the internal reinforcing profiles are created from continuous and/or chopped fiber, wherein the internal reinforcing profiles are entirely surrounded with the thermoplastic material comprising one or more of a non-reinforced thermoplastic material or a thermoplastic material reinforced with a dispersed reinforcement, and wherein the minimum thickness of the thermoplastic material is 0.1 mm and thickness of the internal reinforcing profiles 2, 4, 6, 8, 10, 12, 14, 16 entered to the geotechnical profile is 1.5 – 2.5 mm and coarseness (tex) of the reinforcing fibers is contained within a range of 600 - 5,000 tex. it is pressed through a cross die unit and internal reinforcing profiles in a form of flat bars, arched elements, angled elements, ribbed profiles or sections of any geometry comprising reinforcing fibers are entered at least in selected cross-section areas of the geotechnical profile whereas the internal reinforcing profiles are created from continuous and/or chopped fiber, wherein the internal reinforcing profiles are entirely surrounded with the thermoplastic material comprising one or more of a non-reinforced thermoplastic material or a thermoplastic material reinforced with a dispersed reinforcement, and wherein the minimum thickness of the thermoplastic material is 0.1 mm and thickness of the internal reinforcing profiles 2, 4, 6, 8, 10, 12, 14, 16 entered to the geotechnical profile is 1.5 – 2.5 mm and coarseness (tex) of the reinforcing fibers is contained within a range of 600 - 5,000 tex.
Description
PROFmE The subject of this invention is the method of manufacture of rced geotechnical s, particularly sheet piling profiles and mobile flood prevention devices and geotechnical profiles, particularly sheet piling profiles and mobile flood prevention devices manufactured in this manner, intended for geotechnical purposes. The method of manufacture of geotechnical s allows for forming s profiles applied in civil and marine engineering, as exemplified by sheet piling profiles and mobile flood prevention devices profiles.
Sheet piling profiles are commonly known and frequently used to reinforce embankments or the shorelines of water reservoirs or watercourses. They constitute an alternative to perishable wooden piles requiring periodical maintenance procedures, as well as expensive engineering structures in the form of te breakwaters. They are used, among others, to reinforce and secure water reservoirs and waterbeds, as well as earth structures to increase their tightness and to elevate the tip of river, watercourse and water reservoir embankments and earth structures, to construct water ducts, levees as anti-filtration shields (in drainage, reclamation, tion works and site works to protect against the migration of contaminants), as walls used in the construction and division of water reservoirs, tanks and other fluids, including wastewater treatment plants, for stabilizing excavations and as material for ucting light retaining walls, as anti-erosion protection of reservoirs and watercourses, as anti-chemical shields, as elements of shaping green areas, and to build weirs and road and railway structures. Sheet metal walls are made of steel, te, plastic or structural wood.
Mobile flood prevention devices aim at temporarily securing areas threatened by floods by creating a water-tight wall. All of the currently applied solutions assume systems of aluminum profiles, sandwich boards, gabion and c s, water-filled sleeves or profiles.
Due to the desire to se the durability and strength of geotechnical profiles while reducing the costs of their production, and to reduce or at least maintain the current material consumption and thickness of geotechnical profile walls, their structure is reinforced with additional layers made from various elements.
Among the recorded s regarding geotechnical profiles, the majority focus on technical solutions regarding sheet piling profiles.
Patent description ref. KR 20130129112 presents an at least two-layer sheet piling profiles made of polymer plastic. The internal layer of the sheet piling s is reinforced with glass fiber, and its external layer — with carbon fiber, which constitute the polymer coat enclosed by these . The matrix is made of thermoset resins.
In turn, utility model description ref. CN 203701073 ts a structure, in which areas which are particularly prone local buckling are reinforced at the stage of manufacture, locally producing a composite which constitutes the local stiffening, usually an extension of the sheet pile wall. The matrix is made of thermoset resins.
A method of reinforcing sheet piling profiles is also familiar from patent ref.
CN 203113311, in which the durability of surfaces near the edges of the sheet piling profiles and the edges themselves is increased. The structure of these surfaces comprises glass fiber immersed in resin, which prevents the sheet pile wall from damaging, particularly during its g into the ground. The matrix is made of thermoset resins.
Other familiar methods of manufacture of reinforced plastic profiles consist in continuous ion of profiles applying the pultrusion method, in which continuous fibers are stretched and pulled through an impregnation tank with liquid thermosetting resin and through heated forming dies. The pultrusion technological line also includes profile-heating and pulling devices powered by hydraulic ors and devices g the s to desired sections. To produce higher crosswise durability, a combination of continuous fibers in the form of roving and glass s and mats are used.
A modification of the aforementioned method and a device used for this e is described in patent ref. US 20040001941 concerning both a sion device and the technology itself. Fibers in continuous form are preferably coated with an adhesion promotor and are fed from spools and entered to liquid plastisol to increase the adhesion of polymers to fibers at further stages of the process. The fibers used can be natural or artificial fibers, they can also form fabrics, unwoven fabrics vinyl chloride polymers are preferably homopolymers. In addition, at the stage of gelling, infrared radiation is entered to heat the plastisol and cure the surface of the fiber beams formed into bars. The process of plastisol pultrusion produces reinforcing bars, which are entered to the extruded profiles in the process of co-extrusion.
Known geotechnical profiles reinforced with steel or aluminum profiles have occurred solely in configuration with thermosetting plastics. The use of thermosetting plastics in the known solutions prevents the optimization of geotechnical profile lity in relation to the thickness of their walls (even in the case of steel and aluminum cores), and excludes easy recycling of plastics processed in this manner. The question of recycling is particularly important, since, affected by nmental factors, geotechnical profiles exhibit limited usage periods, and their repurposing while improving the remaining usage parameters solves the problem of waste. Therefore, the goal was to develop a hnical profile and its cture method, which would allow for increasing the durability of the sheet pile wall without increasing its weight, for instance by ucing steel or aluminum profiles, without increasing the l production costs and providing for the recycling of used or damaged geotechnical profiles.
The method of manufacture of reinforced geotechnical profiles according to the invention consists in the cization of thermoplastic material, ably hard and high-impact, PVC and/or PET and/or PE and/or ABS and/or PP, in a presser, after which it is extruded through an cross die unit and internal reinforcing profiles in the form of flat bars, arched ts, angled elements, ribbed profiles or sections of any geometry are entered to it in the entire volume, and at least in selected geotechnical profile cross-section areas, whereas these profiles are created from continuous and/or chopped fiber produced simultaneously or as part of a separate production process. ably, the fiber entered to the structure of the hnical profile is glass, polyester, basalt, aramid, polyamide, steel or natural, plant or animal fiber. Also preferably, the fiber is produced applying the sion method, coating continuous fibers with selected plastic, i.e. PVC and/or PET and/or PE and/or ABS and/or PP. The internal reinforcing profiles are entirely surrounded with non-reinforced thermoplastic matrix and/or thermoplastic matrix rced with dispersed reinforcement, which aim at protecting the fiber against degradation in the working environment. The minimum thickness of the thermoplastic matrix is 0.1 mm. The internal reinforcing s can be obtained through ering of continuous fiber beams, mats and fabrics coated with an impregnate compatible with the polymer matrix, preferably plastisol or hydrogel, or by calibrating continuous fibers, mats and fabrics made of hybrid fibers containing, apart from the basic reinforcing fibers, fibers made of thermoplastic materials.
A reinforced hnical profile ing to the invention is manufactured out of thermoplastic material, preferably hard and high-impact, PVC and/or PET and/or PE and/or ABS and/or PP, in which reinforcement in the form of continuous fibers preferably coated with an adhesion promotor selected from among glass, basalt, ter, aramid, polyamide, steel or natural, plant or animal fiber are entered locally or at least in selected cross—section areas, and then stabilized and maintained in on by a layer/coat made of PVC and/or PET and/or PE and/or ABS and/or PP, which is permanently and rably connected to the continuous fibers. The internal reinforcing profiles contain from 30-90% of the weight of the reinforcing fibers, preferably 70% of the fibers selected from among glass, basalt, aramid, polyamide, steel or natural, plant or animal fiber, and impregnate compatible with the polymer matrix or thermoplastic hybrid fibers in a quantity constituting 10-70% of the l weight of the reinforcing profile, preferably 20- %. The percentage amount of reinforcing fibers, preferably fibers selected from among glass, basalt, aramid, polyamide, steel or l, plant or animal fibers is 5- 50%, preferably 12-16% in on to the overall sheet piling profiles weight.
Internal reinforcing profiles are placed inside the walls of geotechnical profiles situated the farthest from the bending axis of the geotechnical profile.
Internal reinforcing profiles are installed in one, two or multiple layers and are completely surrounded with the polymer matrix. Preferably, the internal reinforcing s are flat bars and/or angled elements and/or ribbed profiles in a single- and/or yer arrangement, preferably of varying widths. Also preferably, the al reinforcing s can be continuous.
The minimum thickness of the polymer matrix in the cross—section ning internal reinforcing profiles is 0.1mm. The polymer matrix is made of thermoplastic material, which can be reinforced with dispersed reinforcement made of chopped fibers.
The process of calendaring or calibrating the internal reinforcing profiles is conducted at temperatures allowing for thermal fusion of the impregnate or adhesion promotor compatible with the polymer matrix or with the thermoplastic hybrid fibers. The process of melting the impregnate or the fibers is conducted with the use of ts generating pressure in the form of heated slide elements — calibrators, or with the use of horizontal and vertical, single-roller, two-roller or multi-roller calendering units, preferably with heated calenders at 50 — 350 °C.
Preferably, the reinforcing fibers are coated with a surface ation or an adhesion promotor, which facilitate fiber impregnation with an impregnate compatible with the thermoplastic matrix.
Preferably, the hybrid fibers are the hybrid fibers of glass fibers with fibers made of thermoplastic materials, such as PET, PE, PVC or PP.
Preferably, in the s of co—extrusion, all external surfaces of geotechnical profiles are coated with a layer of thermoplastic material of at least 0.5 mm in total thickness using a long presser.
The coarseness (teX) of the reinforcing fibers used must be contained between 600 — 5000 teX, preferably 1 000 — 3 000 tex. The thickness of the internal rcing profiles d to the geotechnical profile is 0.5 — 6 mm, ably 1.5-2.5 mm. Preferably, the width of internal reinforcing profiles in the form of flat bars, entered to the sheet pile wall profile or to the geotechnical profiles is 5— 100 mm, preferably 10-50mm, whereas particular s can differ in width.
Preferably, the sheet piling profiles according to the ion has a primary shape of the letter Z, S, U, H, T or Q, or is a hollow profile and ns at least one lock, preferably two locks with mutually complementary shapes. In another, beneficial embodiment of the invention, a mobile flood prevention dam comprises at least two geotechnical profiles with external reinforcing profiles, including a single- or multi-chamber, hollow flood prevention dam wall and a load-bearing profile pillar, preferably a double T-section with proper rigidity, sufficient for founding it in the soil and guaranteeing water—tight installation of the flood prevention dam wall panels.
The profiles of flood prevention dams include seals applied using the co- extrusion method or applying any other method, guaranteeing the water—tightness of the profiles under the re of water.
The hnical profiles manufactured with the method according to the invention have been presented in the figure, in which fig. 1, fig. 2, fig. 3, fig. 4, fig. , fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12 present the cross-section ofthe sheet piling profiles with internal reinforcing profiles in the two-layer arrangement, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, fig. 18, fig. 19, fig. 20, fig. 21, fig. 22, fig. 23, fig. 24, fig 25, fig. 26, fig. 27, fig. 28, fig. 29, fig. 30 present the cross-section of the sheet piling profiles with internal reinforcing profiles in the single-layer ement, fig. 31, fig. 32, fig. 33, fig. 34, fig. 35, fig. 36, fig. 37, fig. 38, fig. 39, fig. 40, fig. 41, fig. 42, fig. 43, fig. 44, fig. 45, fig. 46, fig. 56 present the cross- section of the sheet piling profiles al reinforcing profiles in the single— and two—layer arrangement, fig. 47 ts the cross-section of the sheet piling profiles with continuous internal reinforcing profiles in the two-layer arrangement, fig. 48, fig. 49, fig, 50, fig. 51, fig. 52, fig. 53, fig. 54, fig. 55, fig. 57, fig. 58, fig. 59 present the cross-section of the sheet piling profiles with continuous internal reinforcing profiles in the —layer arrangement, fig. 60 and 61 present reinforcement with an internal, single-layer, continuous ribbed profile, and fig. 62 and 63 present rcement with internal, ribbed reinforcing profiles in the single—layer arrangement, fig. 64, fig. 65, fig. 66 t the cross-section of the profiles of mobile water prevention dams with external reinforcing profiles in the two-layer arrangement.
Example I A geotechnical profile in the form of a sheet piling profiles 1 was manufactured in a manner that hard and high-impact PVC was plasticized in an extruder, after which it was extruded through an cross die unit and internal reinforcing profiles 2 in the form of flat bars and angled elements were entered into it in ed areas of the cross-section of the geotechnical profile 1. The internal reinforcing profiles 2 were installed in two layers and completely surrounded with polymer matrix. The profiles were made of uous fiber, simultaneously manufactured. The fiber entered to the ure of the geotechnical profile is glass fiber. The internal reinforcing profiles 2 are completely nded with non- reinforced, thermoplastic matrix, the e of which is to protect the uous fibers against degradation in the working environment. The minimum thickness of the thermoplastic matrix is 1 mm. The internal rcing profiles 2 were produced through calendering of continuous fiber beams with impregnate compatible with the polymer matrix — plastisol. The internal reinforcing profiles 2 contain 80% glass fibers. The percentage content of reinforcing fibers is 12% in relation to the overall weight of the sheet pile wall profile 1. The internal reinforcing profiles 2 are installed in the walls of the geotechnical profiles 1 situated the farthest from the bending axis. The process of calendering al reinforcing profiles 2 is conducted with the use of horizontal and al, two—roller calendering units with heated calenders at 100 oC. The coarseness (tex) of the reinforcing fibers used is 3000 tex.
The thickness of internal reinforcing profiles entered to the geotechnical profile is 2 mm. The width of internal rcing profiles 2 in the form of flat bars, entered to the sheet pile wall profile 1 is 20 and 35 mm.
Example II A geotechnical profile in the form of a sheet piling profiles 1 was manufactured in a manner that hard and high-impact PVC was plasticized in an extruder, after which it was pressed through an cross die unit and internal reinforcing profiles 2 in the form of flat bars and angle irons were entered into it in selected areas of the cross-section of the geotechnical profile 1. The internal reinforcing profiles 2 were installed in two layers and completely surrounded with polymer matrix. The profiles were made of continuous fiber, simultaneously manufactured. The fiber entered to the ure of the geotechnical profile is hybrid PET fiber / glass fiber. The internal reinforcing profiles 2 are tely surrounded with non—reinforced, thermoplastic matrix, the purpose of which is to protect the continuous fibers against ation in the working environment. The minimum thickness of the thermoplastic matrix is 1 mm. The internal reinforcing profiles 2 were produced through calendering and calibration of continuous hybrid PET / glass fiber beams. The internal rcing profiles 2 comprise hybrid fibers including 70% of glass fibers and 30% of PET fibers. The percentage content of reinforcing fibers is 13% in relation to the overall weight of the sheet pile wall profile 1. The internal reinforcing profiles 2 are installed in the walls of the geotechnical profiles 1 situated the farthest from the bending axis of the geotechnical . The process of calendering and calibration of internal reinforcing profiles 2 is conducted with the use of horizontal and vertical, single- and two-roller calendering units with heated calenders and calibrators at varying temperatures in the range from 220 to 300 oC. The coarseness (tex) of the rcing fibers used is 2700 tex. The thickness of internal reinforcing profiles entered to the geotechnical profile is 2 mm. The width of internal reinforcing s 2 in the form of flat bars, entered to the sheet pile wall profile 1 is 30 mm.
Example 111 A geotechnical profile in the form of a sheet piling profiles 3 was manufactured in a manner that hard and high-impact PVC was plasticized in an extruder, after which it was pressed through an cross die unit and internal reinforcing profiles 4 in the form of flat bars and angled elements were entered into it in selected areas of the cross-section of the geotechnical profile 1. The internal reinforcing profiles 4 were installed in one layer and completely nded with polymer matrix. The profiles were made of continuous fiber, simultaneously manufactured. The fiber entered to the structure of the geotechnical profile 3 is hybrid PET fiber / glass fiber. The internal rcing profiles 4 are tely surrounded with dispersed rcement comprising chopped fibers, the purpose of which is to protect the continuous fibers against degradation in the working environment. The minimum thickness of the thermoplastic matrix is 1.5 mm. The percentage content of chopped glass fiber reinforcing the thermoplastic matrix is %. The internal reinforcing s 4 were produced through calendering uous hybrid PET / glass fiber beams. The internal reinforcing profiles include 80% of hybrid PET fibers. The percentage content of reinforcing fibers is 14% in relation to the overall weight of the sheet pile wall profile 3. The internal reinforcing profiles are installed in the walls of the geotechnical profiles 3 situated the farthest from the bending axis of the geotechnical profile. The process of ering and calibration of internal reinforcing profiles is conducted with the use of horizontal and vertical, two-roller calendering units with heated calenders and calibrators at 220 CC. The coarseness (tex) of the reinforcing fibers used is 2500 tex.
The thickness of internal reinforcing profiles 4 entered to the geotechnical profile 3 is 2 mm. The width of internal rcing profiles 4 in the form of flat bars, entered to the sheet pile wall profile 3 is 30 mm. e IV A geotechnical profile in the form of a sheet piling profiles 3 was manufactured in a manner that hard and high-impact PVC was plasticized in an extruder, after which it was pressed through an cross die unit and internal reinforcing profiles 4 in the form of flat bars and angled elements were d into it in selected areas of the cross-section of the hnical profile, The internal reinforcing profiles 4 were installed in one layer and completely surrounded with polymer matrix. The profiles were made of uous fiber, simultaneously manufactured. The fiber entered to the structure of the geotechnical profile is hybrid PET fiber / glass fiber. The internal reinforcing s 4 are completely surrounded with non—reinforced plastic matrix, the purpose of which is to protect the continuous fibers against degradation in the working environment. The minimum thickness of the thermoplastic matrix is 1.2 mm. The internal reinforcing s 4 were produced h calendering and calibration of continuous hybrid PET / glass fiber beams. The internal reinforcing profiles comprise hybrid fibers including 80% of glass fiber and 20% PET fiber in relation to the overall weight of the sheet piling profile 5. The percentage t of reinforcing fibers is 14% in relation to the overall weight of the sheet pile wall profile 3. The internal reinforcing profiles are installed in the walls of the geotechnical profiles 3 situated the farthest from the bending axis of the geotechnical profile. The process of calendering and calibration of internal reinforcing profiles 4 is ted with the use of horizontal and vertical, single— and two-roller calendering units with heated calenders and calibrators at g temperatures in the range from 220 to 300 oC.
The coarseness (tex) of the reinforcing fibers used is 1600 tex. The thickness of internal rcing profiles entered to the geotechnical profile 2.5 mm. The width of internal reinforcing profiles 4 in the form of flat bars, entered to the sheet pile wall profile 3 is 25-40 mm.
Example V A geotechnical profile in the form of a sheet piling profiles 5 was manufactured in a manner that hard and high-impact PVC was plasticized in an extruder, after which it was pressed through an cross t and internal rcing profiles 6 in the form of flat bars and angle irons were entered into it in selected areas of the cross-section of the geotechnical profile. The internal reinforcing profiles 6 were installed in one and two layers and completely surrounded with polymer matrix. The profiles 6 were made of continuous fiber, simultaneously manufactured. The fiber entered to the structure of the geotechnical profile 5 is hybrid PVC fiber / glass fiber. The internal reinforcing profiles 6 are completely surrounded with plastic matrix reinforced with sed reinforcement made of cut fibers, the purpose of which is to protect the continuous fibers against degradation in the working nment. The minimum thickness of the thermoplastic matrix is 1.2 mm. The percentage content of d glass fiber reinforcing the plastic matrix is 25% in relation to the overall weight of the thermoplastic material. The internal reinforcing profiles 4 were produced through calendering continuous fibers coated with impregnate compatible with the polymer matrix - plastisol. The internal reinforcing profiles 6 made of hybrid fibers include 80% of glass fiber and 20% of PVC fiber in relation to the overall sheet pile wall profile weight. The al reinforcing profiles 6 are installed in the walls of the geotechnical profiles 5 situated the farthest from the bending axis of the geotechnical profile. The process of calendering internal reinforcing profiles is conducted with the use of horizontal and vertical, two-roller calendering units with heated calenders at 100 oC. The coarseness (tex) of the reinforcing fibers used is 3000 tex. The thickness of internal reinforcing profiles 6 entered to the geotechnical profile 5 is 2.2 mm. The width of al reinforcing profiles 6 in the form of flat bars, entered to the sheet pile wall profile 5 is 20 and 40 mm.
Example VI A geotechnical profile in the form of a sheet piling profiles 5 was ctured in a manner that recycled PET, e.g. flakes obtained from the recycling of PET bottles, was plasticized in an extruder, after which it was pressed through an cross die unit and internal reinforcing profiles 6 in the form of flat bars and angled ts were entered into it in selected areas of the cross—section of the geotechnical profile. The internal reinforcing s 6 were installed in one and two layers and completely surrounded with polymer matrix. The s 6 were made of continuous fiber, manufactured in an ndent process. The fiber d to the structure of the geotechnical profile 5 is hybrid PET fiber / glass fiber. The internal reinforcing profiles 6 are completely surrounded with non- reinforced thermoplastic matrix, the purpose of which is to protect the continuous fibers against degradation in the working environment. The minimum thickness of the thermoplastic matrix is 1 mm. The internal reinforcing profiles 6 were produced through ering and ation of continuous hybrid PET / glass fibers. The internal reinforcing profiles 6 made of hybrid fibers include 80% of glass fiber and % of PET fiber in relation to the overall sheet piling profile 5 . The al reinforcing profiles 6 are installed in the walls of the geotechnical profiles 5 situated the farthest from the bending axis of the geotechnical profile. The process of calendering and calibration of internal reinforcing profiles 6 is conducted with the use of ntal and vertical, - and two-roller calendering units with heated calenders and calibrators at varying temperatures in the range from 220 to 300 CC. The coarseness (tex) of the reinforcing fibers used is 2500 tex. The thickness of internal reinforcing profiles 6 entered to the geotechnical profile 5 is 2 mm. The width of internal reinforcing profiles 6 in the form of flat bars, entered to the sheet piling profile 5 is 30 mm. In the process of co-extrusion, all external surfaces of the sheet pile wall profile 5 are coated with a layer of virgin PET of 1 mm using an extruder.
Example VII A geotechnical profile in the form of a sheet piling profiles 5 was manufactured in a manner that recycled PET, e.g. flakes obtained from the recycling of PET bottles, was plasticized in an extruder, after which it was pressed through an cross die unit and internal reinforcing profiles 6 in the form of flat bars and angled elements were entered into it in selected areas of the cross—section of the geotechnical profile. The internal reinforcing profiles 6 were installed in one and two layers and completely surrounded with polymer matrix. The profiles 6 were made of continuous fiber, manufactured in an independent s. The fiber entered to the structure of the geotechnical profile 5 is hybrid PET fiber / carbon fiber. The internal reinforcing profiles 6 are completely surrounded with non- reinforced thermoplastic matrix, the purpose of which is to protect the continuous fibers against degradation in the g nment. The minimum thickness of the thermoplastic matrix is 1 mm. The al reinforcing profiles 6 were produced through calendering and calibration of uous hybrid PET / carbon fibers. The internal reinforcing profiles 6 are made of hybrid carbon fibers and 20% fibers in relation to the overall sheet pile wall profile 5 weight. The internal reinforcing profiles 6 are installed in the walls of the geotechnical profiles 5 situated the farthest from the bending axis of the geotechnical profile. The process of calendering and calibration of internal reinforcing profiles 6 is conducted with the use of horizontal and vertical, single— and ller calendering units with heated ers and calibrators at varying temperatures in the range from 220 to 300 °C. The ness (tex) of the reinforcing fibers used is 2500 tex. The thickness of internal reinforcing s 6 entered to the geotechnical profile 5 is 2 mm. The width of al reinforcing profiles 6 in the form of flat bars entered to the sheet piling profile 5 is mm. In the process of co-extrusion, all al surfaces of the sheet pile wall profile 5 are coated with a layer of virgin PET of 1 mm using an extruder.
Example VIII A geotechnical profile in the form of a sheet piling profile 7 was manufactured in a manner that recycled PET, e.g. flakes ed from the recycling of PET bottles, was plasticized in an extruder, after which it was pressed through an cross t and internal reinforcing profiles 8 in the form of flat bars and angled elements, installed in one and two layers and completely surrounded with polymer matrix, were entered into it in selected areas of the cross-section of the geotechnical profile 7. The profiles 8 were made of continuous fiber, manufactured simultaneously. The fiber entered to the structure of the geotechnical profile 7 is hybrid PET fiber / glass fiber. The internal reinforcing profiles 6 are completely surrounded with thermoplastic matrix reinforced with sed reinforcement made of chopped fiber, the purpose of which is to protect the continuous fibers against degradation in the g environment. The minimum thickness of the thermoplastic matrix is 1 mm. The tage content of chopped glass fiber reinforcing the thermoplastic matrix is 20%. The internal reinforcing profiles 8 were produced through calendering and calibration of continuous hybrid PET / glass fibers. The internal rcing profiles 6 are made of hybrid carbon fibers containing 80% of glass fiber and 20% PET fiber in relation to the overall sheet pile wall profile 7 weight. The internal reinforcing profiles 8 are installed in the walls of the geotechnical profiles 7 situated the farthest from the bending axis of the geotechnical profile. The process of calendering and calibration of internal reinforcing profiles 8 is conducted with the use of horizontal and vertical, single- and two-roller ering units with heated calenders and calibrators at varying temperatures in the range from 220 to 300 0C. The coarseness (tex) of the reinforcing fibers used is 2500 tex. The thickness of internal rcing profiles 8 entered to the geotechnical profile is 1.8 mm. The width of internal reinforcing profiles 8 in the form of flat bars, entered to the sheet piling profile 7 is 28 mm. In the process of co-extrusion, all external es of the sheet piling profile 7 are coated with a layer of virgin PET of 1 mm using an extruder.
Example IX A geotechnical profile 9 was manufactured in a manner that polypropylene ate was plasticized in a single screw extruder, after which it was pressed through an cross die unit and an internal reinforcing profile 10 in the form of a continuous flat bar completely surrounded with polymer matrix, was entered in the entire volume of the geotechnical profile 9. The profile 10 was made of continuous fiber, manufactured parallel (simultaneously). The fiber d to the ure of the geotechnical profile is polypropylene hybrid fiber. The internal reinforcing profile is completely surrounded with non—reinforced thermoplastic matrix, the purpose of which is to t the continuous fibers against degradation in the working environment. The m thickness of the thermoplastic matrix is 1.5 mm. The internal reinforcing profile 10 is made of hybrid PP/glass fibers containing 75% of glass fiber and 25% PP fiber. The percentage content of reinforcing fibers is 18% in relation to the overall weight of the sheet pile wall profile 9. The process of calendering internal reinforcing s is conducted with the use of horizontal and vertical, two-roller calendering units with heated calenders at 250 oC. The ness (tex) of the reinforcing fibers used is 3000 tex. The thickness of the internal reinforcing profile 10 entered to the geotechnical profile 9 is 2.4 mm. The width of the internal reinforcing profile 10 in the form of a flat bar entered to the sheet piling profile 9 is 440 mm.
Example X A geotechnical profile in the form of a sheet piling profiles 9 was manufactured in a manner that polypropylene granulate was plasticized in a single screw extruder, after which it was pressed through an cross die unit and an internal reinforcing profile 10 in the form of flat bars and angled elements were entered in selected areas of the section of the hnical profile 9. The profiles 10 were made of continuous fiber, manufactured aneously. The fiber entered to the structure of the geotechnical profile is polypropylene hybrid fiber. The fiber entered to the structure of the geotechnical profile is hybrid polypropylene fiber.
The internal reinforcing profile 10 is completely surrounded with thermoplastic matrix reinforced with dispersed reinforcement made of cut fiber, the purpose of which is to protect the continuous fibers against degradation in the working environment. The minimum thickness of the thermoplastic matrix is 2 mm. The percentage content of the chopped glass fiber rcing the thermoplastic matrix is %. The internal reinforcing profile 10 was produced through calendering continuous fibers coated with impregnate compatible with the polymer matrix. The al reinforcing profile 10 is made of hybrid PP/glass fibers ning 75% glass fiber and 25% PP fiber. The percentage content of the reinforcing fibers is % in relation to the overall sheet pile wall profile weight. The internal reinforcing profile 10 is installed in the walls of the geotechnical profiles 9 situated the farthest from the bending axis of the geotechnical . The process of calendering the internal rcing profile 10 is conducted with the use of horizontal and vertical, - or two-roller calendering units with heated calenders at 250 CC. The coarseness (tex) of the reinforcing fibers used is 3000 tex. The thickness of the internal reinforcing profile 10 entered to the geotechnical profile is 2.5 mm. The width of the internal reinforcing profile 10 in the form of a flat bar entered to the sheet pile wall profile or geotechnical profiles is 440 mm.
Example XI A geotechnical profile in the form of a sheet piling profiles 11 was manufactured in a manner that HDPE ate was plasticized in a single screw extruder, after which it was pressed through an cross die unit and an internal, single- layer, ribbed profile 11 was entered in the entire volume of the geotechnical profile 11. The profile was made of continuous fiber, manufactured simultaneously. The fiber entered to the structure of the geotechnical profile is polypropylene hybrid fiber. The fiber entered to the structure of the geotechnical profile 11 is made of hybrid HDPE/glass fibers. The internal reinforcing profile 12 is completely surrounded with non—reinforced thermoplastic matrix, the purpose of which is to protect the continuous fibers against degradation in the working environment. The minimum thickness of the thermoplastic matrix is 2.5 mm. The internal reinforcing profile 12 was ed through calendering continuous hybrid PE/glass fibers. The internal reinforcing profile 12 is made of hybrid HDPE/glass fibers containing 75% glass fiber and 25% HDPE fiber. The percentage content of the reinforcing fibers is % in relation to the overall sheet piling profile weight. The al reinforcing profile 12 is installed in the walls of the geotechnical profiles situated the farthest from the g axis of the hnical profile. The process of ering the internal reinforcing profile 12 is conducted with the use of horizontal and vertical, single- and two-roller calendering units with heated calenders at 200 °C. The coarseness (tex) of the rcing fibers used is 3000 tex. The ess of the internal reinforcing profile 12 entered to the geotechnical profile 11 is 2.5 mm. The width of the internal reinforcing profile 12 in the form of a flat bar entered to the sheet pile wall profile 11 is 860 mm. e XII A geotechnical profile 13 was manufactured in a manner that hard and high impact PVC was plasticized in an extruder, after which it was d through an cross die unit and internal reinforcing profiles 14 in the form of single-layer flat bars and angled elements were entered into it in selected areas of the cross-section of the geotechnical profile 13. The s 14 were made of continuous fiber, simultaneously manufactured. The fiber entered to the structure of the geotechnical profile is glass fiber. The internal reinforcing profiles 14 are completely surrounded with non-reinforced thermoplastic matrix, the purpose of which is to protect the continuous fibers against degradation in the g environment. The minimum thickness of the thermoplastic matrix is 1 mm. The internal reinforcing profiles 14 were produced h calendering continuous fibers coated with impregnate compatible with the polymer matrix — hydrogel. The internal reinforcing profiles 14 include 70% of glass fiber. The percentage content of reinforcing fibers is 15% in relation to the overall sheet pile wall profile 13 weight. The internal reinforcing profiles 14 are installed in the walls of the geotechnical profiles13 ed the farthest from the bending axis of the geotechnical profile. The process of calendering and ation of internal reinforcing profiles is conducted with the use of horizontal and vertical, two-roller calendering units with heated calenders at 100 oC. The ness (tex) of the reinforcing fibers used is 3000 tex. The thickness of internal reinforcing profiles 14 entered to the geotechnical profile is 2.5 mm. The width of internal reinforcing profiles 14 in the form of ribbed flat bars entered to the sheet pile wall profile 13 is 20 and 35 mm.
Example XIII A geotechnical profile in the form of a mobile flood prevention dam was ctured in a manner that hard and high-impact PVC was plasticized in an extruder, after which it was pressed through an cross die unit and internal reinforcing profiles 16 in the form of yer fiat bars were entered into it in selected areas of the cross-section of the geotechnical profile 15. The profiles 16 were made of continuous fiber, simultaneously ctured. The fiber entered to the structure of the geotechnical profile is glass fiber. The internal reinforcing profiles 16 are tely surrounded with non-reinforced thermoplastic matrix, the purpose of which is to protect the continuous fibers against ation in the working environment. The minimum thickness of the thermoplastic matrix is 1 mm.
The internal reinforcing profiles 16 were produced h calendering continuous fibers coated with impregnate compatible with the polymer matrix - el. The internal reinforcing profiles 16 include 70% of glass fiber. The percentage content of reinforcing fibers is 15% in relation to the overall sheet pile wall profile 15 weight. The internal reinforcing profiles 16 are installed in the walls of the geotechnical profiles 15 situated the farthest from the bending axis of the geotechnical profile. The process of calendering and calibration of al reinforcing profiles is conducted with the use of horizontal and vertical, two-roller calendering units with heated ers at 110 oC. The coarseness (tex) of the reinforcing fibers used is 3000 tex. The thickness of internal reinforcing profiles 16 entered to the geotechnical profile is 2.5 mm. The width of internal rcing profiles 16 in the form of flat bars entered to the sheet piling profile 15 is 20 and 35 mm. Seals 17 were led on the external surfaces of the profile 15.
One of the advantages of the geotechnical profiles according to the invention is their improved impact properties, higher relative deformation in relation to the thermosetting matrix, which results in lower cracking ty. The fatigue strength of a sheet piling profiles comprising profiles reinforced with continuous fibers with a thermoplastic matrix is significantly higher to the currently used thermosetting matrix. Thermoplastic matrix is recyclable in terms of materials (after shredding, the waste generated from sheet piling profiles with thermoplastic matrix and reinforcing continuous fiber or cut fiber (dispersed) can be used to produce profiles with dispersed fiber reinforcement), which was impossible in the case of thermosetting matrices. Furthermore, the plastics used in the production of the sheet pile wall can come from recycling (high-impact vinyl de can come from the recycling of PVC window frames and PET — from bottle recycling), which significantly reduces the costs of the r matrix. The use of thermoplastic matrix tates the execution of various profile geometries (e. g. hollow sheet pile wall s). The use of thermoplastic matrix facilitates the application of thin external layers by applying the rusion technology, which improves the operational parameters of the products: in the case of thermoplastic matrix made of recycled PVC, it protects the matrix against weather elements, and in the case of a PET matrix — additionally against excessive absorbency.
Claims (28)
1. A method of manufacture of geotechnical profiles, characterized in that thermoplastic material, ably hard and high-impact, PVC and/or PET and/or PE and/or ABS and/or PP, is plasticized in an extruder, after which it is pressed through a cross die unit and internal reinforcing profiles 2, 4, 6, 8, 10, 12, 14, 16 in a form of flat bars, arched elements, angled elements, ribbed profiles or sections of any geometry comprising rcing fibers are entered at least in selected cross-section areas of the geotechnical profile 1, 3, 5, 7, 9, 11, 13, 15, whereas the internal reinforcing profiles are created from continuous and/or chopped fiber, wherein the internal reinforcing profiles are entirely surrounded with the thermoplastic material comprising one or more of a nonreinforced thermoplastic material or a thermoplastic material reinforced with a sed reinforcement, and n the minimum thickness of the thermoplastic material is 0.1 mm and thickness of the internal reinforcing profiles 2, 4, 6, 8, 10, 12, 14, 16 entered to the geotechnical profile 1, 3, 5, 7, 9, 11, 13, 15 is 1.5 – 2.5 mm and coarseness (tex) of the reinforcing fibers is contained within a range of 600 - 5,000 tex.
2. The method according to claim 1, characterized in that the internal reinforcing profiles 2, 4, 6, 8, 10, 12, 14, 16 are produced by calendering continuous fiber beams, mats and fabrics coated with an impregnate compatible with the thermoplastic material and/or by calibrating continuous fibers, mats and fabrics made of hybrid fibers ning, apart from basic fibers, fibers made of plastic materials.
3. The method ing to claim 2, characterized in that plastisol and/or hydrogel is the impregnate compatible with the plastic material.
4. The method according to claim 2 or claim 3, characterized in that the process of calendering or calibrating of the internal reinforcing profiles 2, 4, 6, 8, 10, 12, 14, 16 is conducted at temperatures allowing for thermal fusion of the impregnate or adhesion promotor compatible with the thermoplastic material or with the thermoplastic hybrid fibers.
5. The method ing to any one of claims 2 to 4, characterized in that the process of melting the impregnate or the fibers is conducted with use of ts generating pressure in a form of heated slide elements - calibrators, or with use of horizontal and vertical, single-roller, two-roller or multi-roller ering units.
6. The method according to claim 5, characterized in that the process of melting the impregnate or the fibers is conducted with heated calenders at 50 - 350 °C.
7. The method according to any one of claims 2 to 6, characterized in that the fiber entered to the ure of the geotechnical profile 1, 3, 5, 7, 9, 11, 13, 15 is selected from: glass, basalt, aramid, polyamide, steel or natural, plant or animal fibers.
8. The method according to claim 7, characterized in that the fiber entered to the structure of the geotechnical profile 1, 3, 5, 7, 9, 11, 13, 15 is produced applying a pultrusion method, coating continuous fibers with a selected plastic, i.e. PVC and/or PET and/or PE and/or ABS and/or PP.
9. A rced geotechnical profile, particularly a sheet piling e or a mobile flood prevention device characterized in that it is manufactured out of thermoplastic material ed from hard and high-impact PVC and/or PET and/or PE and/or ABS and/or PP, in which internal reinforcing profiles 2, 4, 6, 8, 10, 12, 14, 16 comprising reinforcing fibers are entered y at least in selected cross-section areas of the geotechnical profile, and stabilized and maintained in position by a layer/coat made of the plastic material selected from PVC and/or PET and/or PE and/or ABS and/or PP, which is permanently and inseparably connected to the fibers, wherein the internal reinforcing profiles are entirely surrounded with the thermoplastic material comprising one or more of a non-reinforced thermoplastic material or a thermoplastic material reinforced with a dispersed reinforcement, and wherein minimum thickness of the thermoplastic al is 0.1 mm and thickness of the internal reinforcing profiles 2, 4, 6, 8, 10, 12, 14, 16 entered to the geotechnical e 1, 3, 5, 7, 9, 11, 13, 15 is 1.5 - 2.5 mm and coarseness (tex) of the reinforcing fibers is contained within a range of 600 - 5,000 tex.
10. The geotechnical e according to claim 9, characterized in that the thermoplastic material is reinforced with a dispersed reinforcement made of chopped fiber.
11. The geotechnical profile according to claim 9, characterized in that the internal reinforcing profiles 2, 4, 6, 8, 10, 12, 14, 16 contain from 30-90% of the weight of the reinforcing fibers and an impregnate compatible with the plastic material or thermoplastic hybrid fibers in a quantity constituting 10-70% of the overall weight of the reinforcing e 2, 4, 6, 8, 10, 12, 14, 16.
12. The geotechnical profile according to claim 9, characterized in that the reinforced hnical profile comprises the reinforcement fibers and thermoplastic hybrid fibers in an amount constituting 12-16% of the weight of the geotechnical profile and n the reinforcement fibers constitute 70% of the weight of the internal reinforcing profiles..
13. The geotechnical profile according to claim 12, characterized in that the hybrid fibers comprise glass fibers and thermoplastic PET, PE, PVC or PP fibers.
14. The geotechnical profile according to any one of claims 11 to 13, characterized in that the reinforcing fibers are ed from: glass, basalt, aramid, polyamide, steel or natural, plant or animal fibers.
15. The geotechnical profile according to any one of claims 9 to 14 , characterized in that the percentage amount of reinforcing fibers is 5-60%.
16. The geotechnical profile according to claim 15, characterized in that the tage amount of rcing fibers is 12-16% in relation to the overall weight of the geotechnical profile 1, 3, 5, 7, 9, 11, 13, 15.
17. The geotechnical profile according to any one of claims 9 to 16, characterized in that the internal reinforcing profiles 2, 4, 6, 8, 10, 12, 14, 16 are placed inside the walls of the geotechnical profile situated the farthest from a bending axis of the geotechnical profile 1, 3, 5, 7, 9, 11, 13, 15.
18. The geotechnical profile ing to claim 17, characterized in that the internal reinforcing profiles 2, 4, 6, 8, 10, 12, 14, 16 are installed in one, two or le layers and are completely surrounded with the thermoplastic material.
19. The geotechnical profile according to claim 18, characterized in that the internal reinforcing es 2, 4, 6, 8, 10, 12, 14, 16 are flat bars and/or ribbed profiles and/or arched profiles and/or angled elements of any geometry in a single- and/or yer arrangement, preferably of varying lengths.
20. The geotechnical profile according to claim 19, characterized in that the internal rcing profiles 2, 4, 6, 8, 10, 12, 14, 16 are continuous.
21. The geotechnical profile according to claim 9 or 10 or 11 or 12 or 13 or 14 or 15 or 16 or 17 or 18 or 19 or 20, characterized in that in a process of co-extrusion, all external surfaces of the geotechnical profile 1, 3, 5, 7, 9, 11, 13, 15 are coated with a layer of a second thermoplastic material of at least 0.5 mm in ess using a second extruder.
22. The geotechnical profile according to claim 9, characterized in that the coarseness (tex) of the reinforcing fibers is contained within a range of 1,000 - 3,000 tex.
23. The geotechnical profile according to any one of claims 9 to 22, characterized in that width of internal reinforcing es 2, 4, 6, 8, 10, 12, 14, 16 in the form of flat bars, entered to the geotechnical profiles 1, 3, 5, 7, 9, 11, 13, 15 is 5-100 mm, whereas particular profiles can differ in width.
24. The geotechnical e ing to claim 23, characterized in that the width of internal reinforcing profiles 2, 4, 6, 8, 10, 12, 14, 16 in the form of flat bars, entered to the geotechnical profiles 1, 3, 5, 7, 9, 11, 13, 15 is 10-50 mm, whereas particular profiles can differ in width.
25. A sheet piling profile comprising a geotechnical profile according to claim 9 or claim 10 or 11 or 12 or 13 or 14 or 15 or 16 or 17 or 18 or 19 or 20 or 21 or 22 or 23 or 24 , characterized in that the sheet piling profile has a primary shape of a letter Z, S, U, Π, T or Ω, or it is a hollow profile and contains at least one locking element.
26. The sheet piling profile ing to claim 25, characterized in that the sheet piling profile has two locking elements with mutually complementary shapes.
27. A mobile flood tion dam comprising at least two geotechnical profiles 15 according to any one of claims 9 to 24 with external reinforcing profiles 16, including a single- or multi-chamber, hollow flood prevention dam wall panel and a aring profile (pillar), preferably a double T-section with proper rigidity, sufficient for founding it in soil and guaranteeing water-tight installation of the flood prevention dam wall panels.
28. The mobile flood prevention dam according to claim 27, characterized in that external es of mobile profiles 15 include seals 17 applied using a co-extrusion method or applying any other method, guaranteeing the tightness of the profiles under the pressure of water.
Applications Claiming Priority (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
PLP.412127 | 2015-04-27 | ||
PL412127A PL412127A1 (en) | 2015-04-27 | 2015-04-27 | Geotechnical sections, preferably the piling sections and mobile flood defences and method for producing reinforced geotechnical sections, preferably the piling sections and mobile flood defences |
PCT/PL2016/050015 WO2016175671A1 (en) | 2015-04-27 | 2016-04-22 | Profile |
Publications (2)
Publication Number | Publication Date |
---|---|
NZ737831A NZ737831A (en) | 2021-06-25 |
NZ737831B2 true NZ737831B2 (en) | 2021-09-28 |
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